JP2004294828A - Optical scanner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical scanner that has a simple constitution, can prevent the joints from excessively warping, and can be driven stably with less power without limiting the range of angles for the incident and reflection light. <P>SOLUTION: Projections 41-44 are provided extending to the outside on the reflection plate 40 supported free to turn through a twistable and deflectable joints 45, 46 inside a frame plate 22. On the frame formed by overlapping three frame plates 22-23, a limiter formed by overlapping frame plate limiter pieces 22e-22h, 23e-23h, 24e-24h is provided to limit the projections 41 to 44 from moving farther than prescribed in the direction along the frame surface. Further, limiter plates 31-34 are formed overlapping each other in front and back of the projections 41-44 to limit them from moving farther than prescribed in the direction orthogonally crossing the frame surface (including the direction turning around the joint 45, 46). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical scanner that rotatably supports a reflecting plate disposed in a frame via a torsionally deformable connecting portion so that a reflection optical axis of light incident on the reflecting plate can be changed. TECHNICAL FIELD The present invention relates to a technique for preventing damage to a connecting portion due to the above.
[0002]
[Prior art]
For example, in a variable wavelength light source, the light emitted from a laser diode is diffracted by a diffraction grating, the diffracted light is reflected by the reflector of the optical scanner to the diffraction grating, and the diffracted light for the reflected light is returned to the laser diode. By oscillating the laser diode in the external resonance mode and changing the angle of the reflector with respect to the diffraction grating, the resonance wavelength is varied.
[0003]
In an optical spectrum analyzer, incident light is diffracted by a diffraction grating, the diffracted light is reflected by a reflection plate of an optical scanner to the diffraction grating, and the diffracted light corresponding to the reflected light is received by a light receiving element and reflected by the diffraction grating. The intensity of light having a wavelength corresponding to the angle of the plate is determined, and the intensity of light for each wavelength is determined by changing the angle of the reflector with respect to the diffraction grating.
[0004]
In recent years, optical scanners used for such purposes are often formed by etching a semiconductor substrate or the like.
[0005]
FIG. 11 shows a basic structure of a conventional optical scanner 10 formed by etching a semiconductor substrate.
[0006]
In this optical scanner 10, a rectangular reflector 12 is arranged inside a frame 11 formed in a rectangular shape by an upper plate 11a, a lower plate 11b, side plates 11c and 11d, and a middle portion of an inner edge of the upper plate 11a of the frame 11 is provided. A structure in which the middle portion of the upper edge of the reflector 12 and the middle portion of the inner edge of the lower plate 11b of the frame 11 to the middle portion of the lower edge of the reflector 12 are connected by the connecting portions 13 and 14. have.
[0007]
Since the connecting portions 13 and 14 are formed to be thin so as to have flexibility in the twisting direction, a force in a direction perpendicular to the surface of the frame 11 is applied to the end of the reflecting plate 12 by a driving unit (not shown). The reflector 12 can be rotated about a line connecting the connecting portions 13 and 14, so that light incident on the reflector 12 can be emitted at different reflection angles.
[0008]
In the optical scanner 10 having such a structure, the thin connecting portions 13 and 14 bend or expand and contract not only in the twisting direction but also in a direction along the surface of the frame 11 and in a direction perpendicular to the surface. It has flexibility.
[0009]
Therefore, as shown in FIG. 12A, when an external force F is applied to the optical scanner 10 from below, the reflection plate 12 moves downward due to the reaction, and the connecting portion 13 is pulled, and the connecting portion 14 is moved. Shrink.
[0010]
Further, as shown in FIG. 12B, when an external force F is applied to the optical scanner 10 from the left side, the reflection plate 12 moves leftward due to the reaction, and the connecting portions 13 and 14 are pulled obliquely. .
[0011]
Also, as shown in FIG. 12C, when an external force F is applied to the optical scanner 10 from the lower left corner, the left end of the reflector 12 moves downward by the reaction, and the right end moves upward, and the connecting portion 13 , 14 are curved.
[0012]
Further, as shown in FIG. 13, when an external force F is applied to the optical scanner 10 from the back side, the reflection plate 12 moves rearward due to the reaction, and the connecting portions 13 and 14 are pulled rearward.
[0013]
Further, as shown in FIG. 14, when an external force F is applied to the optical scanner 10 from the front left side, the left end of the reflector 12 moves forward by the reaction, the right end moves rearward, and the connecting portions 13 and 14 are twisted. Deform.
[0014]
As described above, the connecting portions 13 and 14 of the optical scanner 10 are deformed by the external force F. When the external force is small, the connecting portions 13 and 14 can return to the original state by their own elastic restoring force, but a large external force is applied. Then, it will be deformed or broken.
Therefore, in the optical scanner 10 having the above structure, it is necessary to regulate the connecting portions 13 and 14 so as not to be excessively deformed when receiving an external force.
[0015]
As a conventional technique for restricting excessive deformation of the connecting portions 13 and 14, Japanese Patent Application Laid-Open No. H11-163873 discloses that, as shown in FIG. The overlapping regulating portions 15a and 15b and the overlapping regulating portions 15c to 15f are provided at the four corners of the reflecting plate 12, and these regulating portions 15a to 15f are also provided on the back side of the frame. The movement of a predetermined distance or more is regulated, and furthermore, regulating portions 15g and 15h are provided on both sides of the reflecting plate 12, and regulating portions 15i to 15l are provided above and below both ends of the reflecting plate 12. A technique for restricting movement over a predetermined distance in the left-right direction is disclosed.
[0016]
[Patent Document 1] Japanese Patent Application Laid-Open No. 2002-40354
[Problems to be solved by the invention]
However, in the technique of restricting the movement of the reflection plate 12 as described above, a total of 16 restricting portions are required, and there is a problem that the structure is complicated.
[0018]
In addition, since the restricting portions 15c to 15h are provided close to both ends of the reflecting plate 12, when the reflecting plate 12 is reciprocally swept at a high speed, a large air resistance is generated at both ends due to these restricting portions, and stable. Sweeping cannot be performed, and large power is required for driving.
[0019]
In addition, since the regulating portion overlaps the upper central portion, the lower portion, and the four corners on the front surface side of the reflecting plate 12, the effective reflecting surface of the reflecting plate 12 is narrowed, and the incident angle and the reflecting angle range of light are reduced. There is a problem that is limited.
[0020]
The present invention solves these problems, has a simple structure, can prevent transient deformation of a connecting portion, can be driven stably and with a small amount of power, and has a light incident angle and a reflection angle range which are not limited. It is intended to provide a scanner.
[0021]
[Means for Solving the Problems]
In order to achieve the above object, an optical scanner according to claim 1 of the present invention comprises:
A frame (21);
A reflector (40) arranged inside the frame;
An optical scanner comprising: connecting portions (45, 46) extending inward from opposing positions of the inner edge of the frame and respectively connecting between the outer edges of the reflecting plate, and having flexibility in a twisting direction. ,
Projection pieces (41 to 44, 41 ', 43') extending outward from the outer edge of the reflector are formed on the reflector.
In the frame,
A regulating portion (25 to 28, 25 ', 26', 31) for regulating movement of the projecting piece formed on the reflection plate over a predetermined distance in a direction along the surface of the frame and in a direction orthogonal thereto. To 34) are provided.
[0022]
An optical scanner according to a second aspect of the present invention is the optical scanner according to the first aspect,
The protruding piece of the reflection plate is formed near the connecting portion.
[0023]
An optical scanner according to a third aspect of the present invention is the optical scanner according to the first or second aspect,
The regulating portion of the frame,
Restriction pieces (25 to 28) which extend from the inner edge of the frame to positions adjacent to the side of the projecting pieces of the reflection plate, and regulate the movement of the projecting pieces by a predetermined distance or more in a direction along the surface of the frame. When,
A restricting plate (31 to 34) which overlaps the front and back surfaces of the projecting piece and regulates the movement of the projecting piece by a predetermined distance or more in a direction orthogonal to the surface of the frame. I have.
[0024]
Further, the optical scanner of the present invention,
An optical scanner having a frame (21) and a reflector (40) rotatably mounted in the frame by a pair of connecting portions (45, 46),
Protruding pieces (41 to 44) protruding outward from the outer edge of the reflector toward the frame in the same plane as the reflector and near each of the connecting portions;
The direction from the frame to the reflection plate is provided in the vicinity of each projection so as to be located on both sides of the projection and to limit the fluctuation of the reflection plate in the same plane by contacting the projection. A regulating portion (25 to 28) projecting to
A pair of regulating plates (31 to 34) are provided on the frame near the respective projecting pieces and are spaced in parallel with the same plane, and are brought into contact with the projecting pieces so that the same shape of the reflecting plate is obtained. It is characterized by being constituted by the restricting plates (31 to 34) configured to limit fluctuation in a direction perpendicular to a plane and rotation exceeding a predetermined range around the connecting portion.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 and 2 show the structure of an optical scanner 20 to which the present invention is applied.
[0026]
The optical scanner 20 has a frame 21 having a rectangular outer shape.
The frame 21 has a three-layer structure in which the first frame plate 22 is sandwiched between the second frame plate 23 and the third frame plate 24 from both sides.
[0027]
The first frame plate 22 is formed in a rectangular shape by connecting both ends of a parallel upper plate 22a and lower plate 22b by side plates 22c and 22d.
[0028]
Inside the frame of the first frame plate 22, a rectangular reflecting plate 40 is arranged concentrically. One surface side of the reflection plate 40 forms a reflection surface 40a that reflects light.
[0029]
A middle portion of the inner edge of the upper plate 22a of the first frame plate 22 and a middle portion of the upper edge of the reflector 40 are connected via a connecting portion 45. In addition, between the middle portion of the inner edge of the lower plate 22b facing the inner edge of the upper plate 22a of the first frame plate 22 and the middle portion of the lower edge of the reflection plate 40, the connecting portions 46 aligned with the connecting portion 45 in a straight line. Are connected via
[0030]
The connecting portions 45 and 46 are formed to be thin with flexibility in the twisting direction, and the reflecting plate 40 can be rotated with respect to the first frame plate 22 by the torsional deformation of the connecting portions 45 and 46. It is supported by.
[0031]
Projecting pieces 41, 42 extending outward (in the direction of the upper plate 22 a of the first frame plate 22) with a predetermined width are provided on the upper edge of the reflecting plate 40 in the vicinity of the connecting portion 45 and symmetrically with the connecting portion 45 interposed therebetween. Formed at the location.
[0032]
Also, on the lower edge of the reflecting plate 40, projecting pieces 43, 44 extending outward (in the direction of the lower plate 22 b of the first frame plate 22) and having the same width as the projecting pieces 41, 42 are provided near the connecting portion 46. And are formed at symmetrical positions with the connecting portion 46 interposed therebetween.
[0033]
The first frame plate 22 has restriction pieces 22e to 22e extending from the inner edges of the upper plate 22a and the lower plate 22b so as to approach the outer sides of the projecting pieces 41 to 44 formed on the reflection plate 40, respectively. 22h are provided.
[0034]
The gap between the tip of the upper regulating piece 22e, 22f and the upper edge of the reflector 40 and the gap between the tip of the lower regulating piece 22g, 22h and the lower edge of the reflector 40 are the lengths of the connecting portions 45, 46. The length is set equal to the allowable length of expansion and contraction along the direction (longitudinal direction).
[0035]
Further, the gap between each of the restricting pieces 22e to 22h and each of the protruding pieces 41 to 44 is set to be equal to the allowable length of extension along the horizontal direction orthogonal to the length direction of the connecting portions 45 and 46. .
[0036]
On the other hand, the second frame plate 23 and the third frame plate 24 are the same upper plate 23a, 24a, lower plate 23b, 24b, side plate 23c as the upper plate 22a, the lower plate 22b, and the side plates 22c, 22d of the first frame plate 22. , 23d, 24c, and 24d are formed in a rectangular frame shape, and upper plates 23a, 24a, lower plates 23b, and 24b have the same restriction pieces 23e to 23e to the respective restriction pieces 22e to 22h of the first frame plate 22. 23h, 24e to 24h are provided.
[0037]
As described above, the frame 21 is formed by superposing the second frame plate 23 and the third frame plate 24 on both surfaces of the first frame plate 22, and the three restricting pieces 22e, 23e, 24e superimposed on each other. Thereby, a regulating piece 25 as the frame 21 is formed, a regulating piece 26 is formed by the regulating pieces 22f, 23f, and 24f, and a regulating piece 27 is formed by the regulating pieces 22g, 23g, and 24g, and the regulating pieces 22h, 23h, and 24h. Thus, a regulating piece 28 is formed. The restricting pieces 25 to 28 form restricting portions that restrict the movement of the projecting pieces 41 to 44 of the reflection plate 40 over a predetermined distance in the direction along the surface of the frame 21.
[0038]
Further, between the restricting pieces 25 and 26 on one surface side of the frame 21, the laterally long rectangular restricting plate 31 is horizontally mounted so as to overlap the projecting pieces 41 and 42 of the reflecting plate 40 and the surface side of the connecting portion 45. Then, between the restriction pieces 27 and 28 on one side of the frame 21, the restriction plate 32 having the same shape as the restriction plate 31 is overlapped with the protruding pieces 43 and 44 of the reflection plate 40 and the surface side of the connecting portion 46. It is laid down.
[0039]
Also, between the restriction pieces 25 and 26 on the opposite surface side of the frame 21, a restriction plate 33 having the same shape as the restriction plate 31 overlaps with the protruding pieces 41 and 42 of the reflection plate 40 and the back side of the connecting portion 45. Between the restriction pieces 27 and 28 on the opposite surface side of the frame 21, a restriction plate 34 having the same shape as the restriction plate 31 overlaps the protruding pieces 43 and 44 of the reflection plate 40 and the back side of the connecting portion 46. It is laid to wrap.
[0040]
The gaps (thicknesses of the second frame plate 23 and the third frame plate 24) between each of the regulating plates 31 to 34 and each of the projecting pieces 41 to 44 are allowed to extend along the front and rear directions of the connecting portions 45 and 46. It is set equal to the length.
[0041]
These restricting plates 31 to 34 move a predetermined distance or more in a direction perpendicular to the surface of the frame 21 of each of the protruding pieces 41 to 44 of the reflecting plate 40 (including a rotation direction about the connecting portions 45 and 46 as axes). Forming a regulatory department to regulate.
[0042]
That is, the optical scanner 20 includes the frame 21 and the reflector 40 rotatably mounted in the frame 20 by the pair of connecting portions 45 and 46. The projections 41 to 44 protrude outward from the outer edge of the reflection plate 40 toward the frame 21 in the vicinity of the connection portions 45 and 46, and are provided in the vicinity of the projections 41 to 45, respectively. A restricting portion (a restricting portion) that is located on both sides of the protruding pieces 41 to 45 and protrudes from the frame 21 toward the reflecting plate 40 in order to limit the fluctuation of the reflecting plate 40 in the same plane by contacting the protruding pieces 41 to 45. 25 to 28) and a restricting plate provided on the frame 21 in the vicinity of each of the projecting pieces 41 to 45, and being in contact with the projecting pieces 41 to 45 as a regulating plate spaced in parallel with the same plane. Forty The serial variation and the connecting portions 45 and 46 in the same plane as the vertical direction is adapted to limit the rotation beyond the predetermined range around an axis, is formed by the regulating plates 31 to 34.
[0043]
Next, an example of a method for manufacturing the optical scanner 20 will be described with reference to FIG.
Steps 1a to 1e in FIG. 4 show a manufacturing process of the first frame plate 22 and the third frame plate 24 constituting the frame 21. First, as the substrate material, the active layer 100a having a high conductivity and a mirror finish is used. An SOI substrate 100 is prepared by laminating an insulating layer (SiO ₂ ) 100c with a base substrate 100b (step 1a).
[0044]
Then, on the surface of the active layer 100a, portions where the upper plate 22a, the lower plate 22b, the side plates 22c and 22d, and the restriction pieces 22e to 22h are formed on the surface of the active layer 100a so that the ICP-RIE device can perform the etching process. Then, a mask 101 is formed on the portion where the reflection plate 40 and the projecting pieces 41 to 44 are formed and the portion where the connecting portions 45 and 46 are formed by using the photolithography technique (step 1b).
[0045]
Next, the active layer 100a not covered with the mask 101 is etched by an ICP-RIE apparatus to form the first frame plate 22, and the mask 101 is removed (step 1c).
[0046]
Next, a mask 102 is formed on a portion of the surface of the base substrate 100b where the upper plate 24a, the lower plate 24b, the side plates 24c and 24d, and the restriction pieces 24e to 24h are formed (step 1d).
[0047]
Next, the base substrate 100b that is not covered with the mask 102 is etched to form a portion of the third frame plate 24, and the mask 102 is removed (Step 1e).
[0048]
Then, a portion of the insulating layer 100c exposed on the surface is removed by etching (step 1f).
[0049]
Through the above steps, a two-layer structure portion of the first frame plate 22 and the third frame plate 24 including the reflection plate 40 and the connecting portions 45 and 46 in the frame 21 is completed.
[0050]
On the other hand, in another step 2a, a silicon substrate 200 is prepared, and on the surface thereof, the upper plate 23a, the lower plate 23b, the side plates 23c, 23d, and the formation portions of the respective restriction pieces 23e to 23h of the second frame plate 23 are formed. A mask 201 is formed (Step 2b).
[0051]
Next, the substrate 200 not covered with the mask 201 is etched to form the second frame plate 23, and the mask 201 is removed (step 2c).
[0052]
Then, the portion of the second frame plate 23 obtained in the step 2c is bonded to the first frame plate 22 obtained in the step 1f with an insulating layer 202 (which may also serve as an adhesive) interposed therebetween (step). 3).
[0053]
Finally, regulating plates 31 to 34 are adhered between the front and back sides of the regulating pieces 25 and 26, and between the front and back sides of the regulating pieces 27 and 28, respectively. It is completed (Step 4).
[0054]
Since the reflection plate 40 of the optical scanner 20 has conductivity, a voltage is applied between the reflection plate 40 and a fixed electrode (not shown) facing an end of the reflection plate 40, and the reflection plate 40 By applying an electrostatic force to the end, the angle of the reflector 40 can be changed by rotating the reflector 40 about the connecting portions 45 and 46. Further, by periodically applying a voltage, that is, by giving a signal in which the voltage changes periodically, the reflecting plate 40 can be reciprocated.
[0055]
As a method for rotating the reflection plate 40, there is a method using magnetic force in addition to the method using electrostatic force as described above. For example, a member or a film that is attracted by magnetic force is provided on the reflection plate 40 side, and an electric current is applied to a fixed coil facing the portion to rotate the reflection plate 40 by the magnetic force of the fixed coil. Conversely, a coil may be provided on the reflection plate 40 side or a pattern may be formed on the surface thereof, and the reflection plate 40 may be rotated by a magnetic force generated by passing a current through the coil.
[0056]
When a large external force F is applied to the optical scanner 20 configured as described above from below, for example, as shown in FIG. Is pulled, and the connecting portion 46 shrinks, but the lower edge of the reflector 40 abuts against the tips of the restricting pieces 27 and 28 of the frame 21 to restrict the movement of a predetermined distance or more. No deformation beyond. Conversely, when a large external force is applied from above, the upward movement of the reflector 40 by a predetermined distance or more due to the reaction is restricted by the restricting pieces 25 and 26, and exceeds the limit of the connecting portions 45 and 46. Deformation is prevented.
[0057]
Also, as shown in FIG. 5B, when a large external force F is applied to the optical scanner 20 from the left side, the reflection plate 40 moves leftward due to the reaction, and the connecting portions 45 and 46 are pulled obliquely. However, since the protruding pieces 41 and 43 of the reflection plate 40 abut on the restricting pieces 25 and 27 of the frame 21 to restrict the movement of a predetermined distance or more, the deformation exceeding the limit of the connecting portions 45 and 46 does not occur. On the other hand, when a large external force is applied from the right side, the movement of the reflection plate 40 to the right by a predetermined distance or more due to the reaction is restricted by the restriction pieces 26 and 28, and the limit of the connecting portions 45 and 46 is limited. Is prevented.
[0058]
When a large external force F is applied to the optical scanner 20 from the lower left corner (or upper right corner) as shown in FIG. 5C, the reaction causes the left end of the reflector 40 to move downward and the right end to move upward. As a result, the connecting portions 45 and 46 are curved, but the protruding pieces 41 and 44 of the reflector 40 abut against the restricting pieces 25 and 28 of the frame 21 to restrict the rotation beyond a predetermined angle. Therefore, the deformation exceeding the limit of the connecting portions 45 and 46 does not occur. On the other hand, when a large external force is applied from the lower right corner (or upper left corner), the counterclockwise rotation of the reflector 40 by a predetermined angle or more due to the reaction is restricted by the restricting pieces 26 and 27, and the connecting portion 45 is formed. , 46 are prevented.
[0059]
Also, as shown in FIG. 6, when an external force F is applied to the optical scanner 20 from the back side, the reflection plate 40 moves rearward due to the reaction, and the connecting portions 45 and 46 are pulled obliquely. Since the protruding pieces 41 to 44 abut against the regulating plates 33 and 34 of the frame 21 to regulate the movement of the connecting pieces 45 and 46 beyond a predetermined distance, the deformation of the connecting portions 45 and 46 beyond the limit does not occur. On the other hand, when a large external force is applied from the front, the movement of the reflector 40 forward by a predetermined distance or more by the reaction is regulated by the regulating plates 31 and 32, and exceeds the limit of the connecting portions 45 and 46. Deformation is prevented.
[0060]
Further, as shown in FIG. 7, when a large external force F is applied from the front left end (or from the rear right end) of the optical scanner 20, the left end of the reflection plate 40 moves forward by the reaction, and the right end moves rearward to return. When rotated clockwise, the connecting portions 45 and 46 are torsionally deformed. However, the projecting pieces 41 and 43 of the reflecting plate 40 abut against the regulating plates 31 and 32, and the projecting pieces 42 and 44 abut against the regulating plates 33 and 34. Since the rotation of the connecting portions 45 and 46 is restricted, the deformation of the connecting portions 45 and 46 beyond the limit does not occur. On the other hand, when a large external force is applied from the rear left end (or the front right end), the clockwise rotation of the reflection plate 40 by a reaction is restricted by the restriction plates 31 to 34 by the restriction plates 31 to 34. Deformation beyond the limits of 45, 46 is prevented.
[0061]
As described above, the optical scanner 20 of the embodiment has the projections 41 to 44 provided on the outer edge of the reflection plate 40, and moves the projections 41 to 44 by a predetermined distance or more on each of the restriction pieces 25 to 44 provided on the frame 21. 28 and regulating plates 31 to 34.
[0062]
Therefore, excessive deformation of the connecting portions 45 and 46 can be prevented with a small number of restricting portions, and the structure can be simplified.
[0063]
In addition, since the projecting pieces 41 to 44 provided near the connecting portions 45 and 46 are regulated, there is no need to provide regulating portions near both ends of the reflector 40, and when the reflector 40 is reciprocally swept at high speed. However, the air resistance can be reduced, stable sweeping can be performed, and the rotary drive can be performed with less power. Further, the movement of the plurality of projecting pieces can be regulated by one regulating plate, and the number of members for regulation can be reduced.
[0064]
Further, since it is not necessary to overlap the restricting portion with the reflecting plate 40, one surface of the reflecting plate 40 can be effectively used as a reflecting surface, and the incident angle and the reflecting angle range of the light are not limited.
[0065]
Here, a drive system is assumed in which a voltage is applied between the reflector 40 and an electrode facing the end and the reflector 40 is rotated by an electrostatic force generated between the reflector 40 and the reflector 40. The first frame plate 22 including the connecting portions 45 and 46 is formed of a substrate material having high conductivity, but this does not limit the present invention. When a drive system for rotating the mirror is used, the reflection plate 40 may be formed of an insulating substrate material, and a film or a coil receiving a magnetic force may be provided on the end surface thereof.
[0066]
Further, the substrate material is mirror-finished to form the reflection surface 40a for reflecting light on the surface of the reflection plate 40. However, a reflection film may be formed on the surface of the reflection plate 40 using a material having a high reflectance. .
[0067]
In addition, the shapes and arrangements of the restricting portions of the frame 21 and the protruding pieces 41 to 44 of the reflection plate 40 are not limited to the above-described embodiment, but can be variously modified.
[0068]
For example, as shown in FIG. 8, the tip shape of each of the restriction pieces 25 to 28 is formed in an L-shape according to the tip corner of each of the protruding pieces 41 to 44 of the reflection plate 40, and they are close to each other so as to engage with each other. In the direction along the surface of the frame 21, not only the movement of the reflector 40 in the left and right directions, but also the movement of the reflection plate 40 by a predetermined distance or more, and the rotation by a predetermined angle or more, each of the restriction pieces 25 with respect to the protruding pieces 41 to 44. Alternatively, the contact may be restricted by the contact of Nos. To 28.
[0069]
In contrast to the example of FIG. 8, as shown in FIG. 9, the tip shape of each of the protruding pieces 41 to 44 is formed in an L-shape so as to match the tip corners of each of the restricting pieces 25 to 28 and engaged with each other. May be brought close to each other.
[0070]
Further, as shown in FIG. 10, a protruding piece 41 'is provided at the center of the upper edge of the reflector 40, and a protruding piece 43' is provided at the center of the lower edge, and the protruding pieces 41 'and 43' are provided on the surface of the frame 21. The movement of a predetermined distance or more in the along direction may be restricted by the restriction pieces 25 to 28, and the movement of a predetermined distance or more in the direction orthogonal to the surface of the frame 21 may be restricted by the restriction plates 31 to 34.
[0071]
Although not shown, the restriction pieces 25 to 28 may be adjacent to the inner sides of the respective protruding pieces 41 to 44.
[0072]
In the optical scanner 20, the case where the outer shapes of the frame 21 and the reflecting plate 40 are rectangular has been described. However, these outer shapes are not limited to rectangles, and may be elliptical, circular, polygonal, and the like. Good.
[0073]
【The invention's effect】
As described above, in the optical scanner of the present invention, in order to prevent the connecting portion from being excessively deformed or damaged by an external force, a projecting piece is provided on the outer edge of the reflector, and the movement of the projecting piece is applied to the frame. It is regulated by the regulation section provided.
[0074]
For this reason, excessive deformation of the connecting portion can be prevented with a small number of restricting portions, and the structure can be simplified.
[0075]
Further, since it is not necessary to overlap the restricting portion with the reflecting surface of the reflecting plate, an effective wide reflecting surface can be formed on the reflecting plate, and the incident angle and the reflecting angle range of light are not limited.
[0076]
Also, when the protruding piece is provided near the connecting portion, there is no need to restrict the movement of both ends of the reflector, and even when the reflector is swept at high speed, the air resistance is small and stable. Sweeping and can be driven with low power.
[Brief description of the drawings]
FIG. 1 is a perspective view of an embodiment of the present invention as viewed from the front side. FIG. 2 is a perspective view of an embodiment of the present invention as viewed from the back side. FIG. 3 is an exploded perspective view of the embodiment. FIG. FIG. 5 is an explanatory diagram of an operation of the embodiment. FIG. 6 is an operational explanatory diagram of the embodiment. FIG. 7 is an operational explanatory diagram of the embodiment. FIG. 8 is a diagram showing a modified example of the embodiment. FIG. 9 is a diagram showing a modification of the embodiment; FIG. 10 is a diagram showing a modification of the embodiment; FIG. 11 is a basic configuration diagram of the optical scanner; FIG. 12 is a diagram for explaining deformation due to external force; FIG. 14 is a diagram for explaining deformation due to external force. FIG. 14 is a diagram for explaining deformation due to external force. FIG. 15 is a diagram showing a conventional regulating method for preventing transient deformation.
Reference numeral 20: optical scanner, 21: frame, 22: first frame plate, 23: second frame plate, 24: third frame plate, 25 to 28: regulating piece, 31 to 34: regulating plate , 40 ... reflecting plate, 41-44 ... projecting piece, 45, 46 ... connecting part

Claims (3)

A frame (21);
A reflector (40) arranged inside the frame;
An optical scanner comprising: connecting portions (45, 46) extending inward from opposing positions of the inner edge of the frame and respectively connecting between the outer edges of the reflecting plate, and having flexibility in a twisting direction. ,
Projection pieces (41 to 44, 41 ', 43') extending outward from the outer edge of the reflector are formed on the reflector.
In the frame,
A regulating portion (25 to 28, 25 ', 26', 31) for regulating movement of the projecting piece formed on the reflection plate over a predetermined distance in a direction along the surface of the frame and in a direction orthogonal thereto. 34) An optical scanner comprising: The optical scanner according to claim 1, wherein the projecting piece of the reflection plate is formed near the connecting portion. The regulating portion of the frame,
Restriction pieces (25 to 28) which extend from the inner edge of the frame to positions adjacent to the side of the projecting pieces of the reflection plate, and regulate the movement of the projecting pieces by a predetermined distance or more in a direction along the surface of the frame. When,
A regulating plate (31-34) that overlaps the front and back surfaces of the protruding piece and restricts the movement of the protruding piece by a predetermined distance or more in a direction perpendicular to the surface of the frame. The optical scanner according to claim 1 or 2, wherein

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